Mass spring damper system not working

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Dirk te Brake il 6 Mag 2024

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Commentato: Dirk te Brake il 7 Mag 2024

RealWorldData.mat

I'm solving an ode45 for a mass spring damper system as shown below. But the results i'm getting don't oscillate as much as they should. I have seen other questions about this (link) but can not get it to work. All help is apprecriated, thanks.

%% Initialisation
clc;
close all;
clear; 
load("RealWorldData.mat")
m_total =[ 363.5  463.7   363.5 ; 563.9  663.1   563.9 ; 764.3  864.5  764.3]; % Different masses
m = m_total(2,:); % Masses used
t_end = 20; % Time in seconds
w = 5; % Staitionary frequency
k = 40; % Spring constant
b = 0.2; % Friction constant
%% Calculations
t = [0 t_end]; % Time period
x0 = [0, 0, 0, 0, 0, 0, 0]; % Initial conditions
Change = ischange(RealX); 
index = find(Change,1,'first'); % Starting point realdata
index2 = find(Change,1,'last'); % Ending point realdata
RealX = RealX(index:index2,:)*0.001; 
RealT = (1:length(RealX)).*0.001;
[Time,X] = ode45(@(t,x)MassSpringFunction(t,x,m,w,k,b),t,x0);
displacement = X(:,1:3);
velocity = X(:,4:6);
%% Plotting
figure
plot(Time,displacement)
hold on 
plot(RealT,RealX)
legend("RealWorldData","U1" , "U2" , "U3")

%% System
function dxdt = MassSpringFunction(t, x, m, w, k, b)
% Acceleration of 10 hz/s
Freq = 2*pi*10*t;
if w > Freq % Acceleration of frequency
    xin = sin(Freq.*t);
else % Stationairy input
    xin = sin(2*pi*w.*t);
end
dxdt = zeros(6,1);
% Velocities
dxdt(1) = x(4);
dxdt(2) = x(5);
dxdt(3) = x(6);
% Positions
dxdt(4) = -k/m(1) .* (x(1) - xin)  - k/m(1).*(x(1)-x(2)) - b/m(1).*x(4);
dxdt(5) = -k/m(2) .* (x(2) - x(1)) - k/m(2).*(x(2)-x(3)) - b/m(2).*x(5);
dxdt(6) = -k/m(3) .* (x(3) - x(2)) - k/m(3).*(x(3)     ) - b/m(3).*x(6);
end

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Sam Chak il 6 Mag 2024

Spostato: Sam Chak il 6 Mag 2024

Apri in MATLAB Online

Hi @Dirk te Brake

I didn't review your model as you didn't provide the derivation steps. However, I made a change by switching the signs from 'plus' to 'minus'. This adjustment ensures that the system's energy is dissipated through negative kinetic energy flow, aligning with the principles of physics.

% Mass

m_total = [363.5 463.7 363.5;

563.9 663.1 563.9;

764.3 864.5 764.3];

m = m_total(2,:);

% Staitionary frequency

w = 5;

% Constants for springs

k = 80;

b = 0.2;

t = [0 40];

x0 = [0, 0, 0, 0, 0, 0];

[Time,x]= ode45(@(t, x) MassSpringFunction(t, x, m, w, k, b), t, x0);

figure(1)

plot(Time,x(:,1))

hold on

plot(Time,x(:,3))

plot(Time,x(:,5))

legend("U1" , "U2" , "U3")

hold off

grid on

xlabel('t')

ylabel('\bf{U}')

%% System

function dxdt = MassSpringFunction(t, x, m, w, k, b)

% Acceleration of 10 hz/s

Freq = 2*pi*10*t;

if w > Freq % Acceleration of frequency

xin = sin(Freq.*t);

else % Stationairy input

xin = sin(2*pi*w.*t);

end

dxdt = zeros(6,1);

% Velocities

dxdt(1) = x(4);

dxdt(2) = x(5);

dxdt(3) = x(6);

% Positions

dxdt(4) = - k/m(1) .* (x(1) - xin ) - k/m(1).*(x(1) - x(2)) - b/m(1).*x(4);

dxdt(5) = - k/m(2) .* (x(2) - x(1)) - k/m(2).*(x(2) - x(3)) - b/m(2).*x(5);

dxdt(6) = - k/m(3) .* (x(3) - x(2)) - k/m(3).*(x(3) ) - b/m(3).*x(6);

end

Sam Chak il 6 Mag 2024

Spostato: Sam Chak il 6 Mag 2024

Hi @Dirk te Brake

Could you please extract the data and save it in the mat-file? Additionally, ensure that the code is updated where amplitude = 0.05 should be. If the simulated data doesn't match the real-world data, it's highly likely that your proposed mathematical model doesn't accurately capture the real-world dynamics. While the block masses can be measured fairly accurately with the right instruments, the dashpot coefficient (b) and the spring stiffness (k) need to be determined experimentally or through system identification tools.

@Star Strider has extensive experience in this topic and has provided numerous solutions. It is advised that you revise or update the question with additional context based on their expertise.

The solutions provided in the following two links may be helpful for your questions:

Finding Unknown Parameters from Monod Equations: link
Parameters Identification Providing Derivative: link

Since you have real-world data, the codes provided in these solutions could be beneficial.

Sam Chak il 7 Mag 2024

Apri in MATLAB Online

RealWorldData.mat

Hi @Dirk te Brake

Based on the laws of physics, the derived model of the mass-spring-damper system with the external sinusoidal force,

cannot accurately reproduce the response that matches the provided real-world measured unscaled data.

Firstly, there appears to be a delay in the real-world data, but this delay is not accounted for in the mathematical model. Secondly, when coupled mass systems are subjected to an external undamped sinusoidal input signal, they typically exhibit repetitive oscillatory patterns at specific periodic intervals. However, no such repetitive patterns are observed in the real-world data.

Hence, there might be some missing information. I recommend checking with your teacher for further clarification.

load("RealWorldData.mat")

plot(RealX), grid on, xlabel('Number of Samples'), ylabel('Amplitude'), title('Real-world data')